IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0486132
(2009-06-17)
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등록번호 |
US-8225081
(2012-07-17)
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발명자
/ 주소 |
- Aldereguia, Alfredo
- Richter, Grace A.
- Schwartz, William B.
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출원인 / 주소 |
- International Business Machines Corporation
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
19 인용 특허 :
7 |
초록
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Updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each compute node of the SMP computer including a PLD coupled for data communications through a bus adapter, the bus adapter adapted for data communications through a set of one or more input/output (‘I/O’)
Updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each compute node of the SMP computer including a PLD coupled for data communications through a bus adapter, the bus adapter adapted for data communications through a set of one or more input/output (‘I/O’) memory addresses, including configuring the primary compute node with an update of the configuration instructions for the PLDs; assigning, by the PLDs at boot time in an SMP boot, a unique, separate set of one or more I/O addresses to each bus adapter on each compute node; and providing, by the primary compute node during the SMP boot, the update to all compute nodes, writing the update as a data transfer to each of the PLDs through each bus adapter at the unique, separate set of one or more I/O addresses for each bus adapter.
대표청구항
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1. A method of updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each PLD configured according to configuration instructions installed within each PLD, the SMP computer comprising a plurality of compute nodes including a primary compute node and one or mor
1. A method of updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each PLD configured according to configuration instructions installed within each PLD, the SMP computer comprising a plurality of compute nodes including a primary compute node and one or more secondary compute notes, the compute nodes sharing a same memory address space, each compute node further comprising a PLD coupled for data communications to at least one computer processor through a bus adapter, the bus adapter adapted for data communications through a set of one or more input/output (‘I/O’) memory addresses, each bus adapter defaulting, upon a stand-alone boot, to a same set of one or more I/O memory addresses,the method comprising:configuring the primary compute node with an update of the configuration instructions for the PLDs;assigning, by the PLDs at boot time in an SMP boot, a unique, separate set of one or more I/O addresses to each bus adapter on each compute node; andproviding, by the primary compute node during the SMP boot, the update to all compute nodes, writing the update as a data transfer to each of the PLDs through each bus adapter at the unique, separate set of one or more I/O addresses for each bus adapter. 2. The method of claim 1 wherein each PLD comprises only one of: a complex programmable logic device (‘CPLD’), a field programmable gate array (‘FPGA’), or a programmable system-on-chip (‘PSOC’). 3. The method of claim 1 further comprising: setting by each PLD an update-complete bit accessible by the primary compute node;tracking by the primary compute node the number of update-complete bits that have been set; anddetermining by the primary compute node that the update process is complete when the number of set update-complete bits is equal to the number of compute nodes in the SMP computer. 4. The method of claim 1 further comprising powering off, including removing standby power from the PLDs, and powering on in unison all the of the compute nodes in the SMP computer, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions. 5. The method of claim 1 further comprising: determining by the primary compute node that all compute nodes have successfully received the update of the configuration instructions;sending by the primary compute node to all of the compute nodes an instruction to power off for a predetermined period of time;responsive to the instruction to power off, powering off by all the compute nodes for the predetermined period of time, including removing standby power from the PLDs for the predetermined period of time; andpowering on by all the compute nodes after the predetermined period of time, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions. 6. Apparatus for updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each PLD configured according to configuration instructions installed within each PLD, the SMP computer comprising a plurality of compute nodes including a primary compute node and one or more secondary compute notes, the compute nodes sharing a same memory address space, each compute node further comprising a PLD coupled for data communications to at least one computer processor through a bus adapter, the bus adapter adapted for data communications through a set of one or more input/output (‘I/O’) memory addresses, each bus adapter defaulting, upon a stand-alone boot, to a same set of one or more I/O memory addresses,the apparatus comprising a computer processor, a computer memory operatively coupled to the computer processor, the computer memory having disposed within it computer program instructions capable of causing the apparatus to carry out the steps of:configuring the primary compute node with an update of the configuration instructions for the PLDs;assigning, by the PLDs at boot time in an SMP boot, a unique, separate set of one or more I/O addresses to each bus adapter on each compute node; andproviding, by the primary compute node during the SMP boot, the update to all compute nodes, writing the update as a data transfer to each of the PLDs through each bus adapter at the unique, separate set of one or more I/O addresses for each bus adapter. 7. The apparatus of claim 6 wherein each PLD comprises only one of: a complex programmable logic device (‘CPLD’), a field programmable gate array (‘FPGA’), or a programmable system-on-chip (‘PSOC’). 8. The apparatus of claim 6 further comprising computer program instructions capable of causing the apparatus to carry out the steps of: setting by each PLD an update-complete bit accessible by the primary compute node;tracking by the primary compute node the number of update-complete bits that have been set; anddetermining by the primary compute node that the update process is complete when the number of set update-complete bits is equal to the number of compute nodes in the SMP computer. 9. The apparatus of claim 6 further comprising computer program instructions capable of causing the apparatus to carry out the steps of powering off, including removing standby power from the PLDs, and powering on in unison all the of the compute nodes in the SMP computer, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions. 10. The apparatus of claim 6 further comprising computer program instructions capable of causing the apparatus to carry out the steps of: determining by the primary compute node that all compute nodes have successfully received the update of the configuration instructions;sending by the primary compute node to all of the compute nodes an instruction to power off for a predetermined period of time;responsive to the instruction to power off, powering off by all the compute nodes for the predetermined period of time, including removing standby power from the PLDs for the predetermined period of time; andpowering on by all the compute nodes after the predetermined period of time, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions. 11. A computer program product for updating programmable logic devices (‘PLDs’) in a symmetric multiprocessing (‘SMP’) computer, each PLD configured according to configuration instructions installed within each PLD, the SMP computer comprising a plurality of compute nodes including a primary compute node and one or more secondary compute notes, the compute nodes sharing a same memory address space, each compute node further comprising a PLD coupled for data communications to at least one computer processor through a bus adapter, the bus adapter adapted for data communications through a set of one or more input/output (‘I/O’) memory addresses, each bus adapter defaulting, upon a stand-alone boot, to a same set of one or more I/O memory addresses,the computer program product disposed in a recordable, computer-readable storage device, the computer program product comprising computer program instructions which when executed on the SMP computer case the SMP computer to carry out the steps of:configuring the primary compute node with an update of the configuration instructions for the PLDs;assigning, by the PLDs at boot time in an SMP boot, a unique, separate set of one or more I/O addresses to each bus adapter on each compute node; andproviding, by the primary compute node during the SMP boot, the update to all compute nodes, writing the update as a data transfer to each of the PLDs through each bus adapter at the unique, separate set of one or more I/O addresses for each bus adapter. 12. The computer program product of claim 11 wherein each PLD comprises only one of: a complex programmable logic device (‘CPLD’), a field programmable gate array (‘FPGA’), or a programmable system-on-chip (‘PSOC’). 13. The computer program product of claim 11 further comprising computer program instructions which when executed on the SMP computer case the SMP computer to carry out the steps of: setting by each PLD an update-complete bit accessible by the primary compute node;tracking by the primary compute node the number of update-complete bits that have been set; anddetermining by the primary compute node that the update process is complete when the number of set update-complete bits is equal to the number of compute nodes in the SMP computer. 14. The computer program product of claim 11 further comprising computer program instructions which when executed on the SMP computer case the SMP computer to carry out the steps of: powering off, including removing standby power from the PLDs, and powering on in unison all the of the compute nodes in the SMP computer, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions. 15. The computer program product of claim 11 further comprising computer program instructions which when executed on the SMP computer case the SMP computer to carry out the steps of: determining by the primary compute node that all compute nodes have successfully received the update of the configuration instructions;sending by the primary compute node to all of the compute nodes an instruction to power off for a predetermined period of time;responsive to the instruction to power off, powering off by all the compute nodes for the predetermined period of time, including removing standby power from the PLDs for the predetermined period of time; andpowering on by all the compute nodes after the predetermined period of time, booting the compute nodes in SMP mode, thereby reconfiguring the PLDs according to the updated configuration instructions.
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